EP1064484B1 - Electromechanical actuator for a valve and steam turbine - Google Patents

Description

The invention relates to an electromechanical actuator for a valve of a turbine, with a push rod for setting an opening position of the valve and with an electric motor to drive the push rod. The invention further relates to a steam turbine with a valve and an associated actuator.

A turbine, in particular a steam turbine, usually has a considerable number of valves, for example as live steam, interception or diverter valves as well can be used as quick-closing valves. The The opening position of each of these valves is used for adjustment of a respective material or steam flow and is e.g. via a push rod assigned to the respective valve adjustable. Such a push rod is part of a actuator associated with the valve. To the actuator can, especially with regard to positioning force and Positioning speed, high demands are made. For A high reliability of the valve can, for example be required that the actuator has an actuating force of about 200 kN and a positioning time of about 100 ms.

EP 0 040 732 A1 describes an actuator for steam turbine valves indicated that of a decentralized hydraulic system having. The hydraulic system of such an actuator is a compact drive block arranged on the valve housing integrated so that for an energy supply of Actuator only requires a cable system is. By using oil as hydraulic fluid could ignite in extremely unfavorable circumstances of the oil and thus lead to a fire in the steam turbine.

DE 44 46 605 A1 describes a valve for a steam turbine indicated which a valve stem with an arranged thereon Has valve cone. The valve stem is over one Electric motor driven, which is electromagnetic actuated clutch is connected to the valve stem. For This includes automatic self-closing of the valve a disc spring system. The electromagnetic clutch is connected with a threaded bushing, which with the rotationally fixed guided valve spindle cooperates and so this axially emotional. The threaded bushing is designed as a ball screw bushing, so that the valve spindle is free from play and friction applied. Due to the non-rotatable guidance of the valve spindle, i.e. this is only when the threaded bushing is rotating axially up and down, is not translationally effective Drive required. Rather, one is sufficient for this electric motor rotating in two directions. The electric motor However, it must have a torque lock in order to this way to prevent, for example, when closing of the valve that connects to the valve stem at one end Valve cone attaches itself to the one assigned to it The sealing seat is not damaged or the sealing seat is damaged.

DE 36 18 479 A1 describes a fitting for shutting off one Flow out, with a housing in which a closure piece with the help of a thread between the open and closed end positions is movable with a rotary drive (drive motor) with time delay is switched off. Between the Rotary drive and the closure piece is a gearbox with two concentrically arranged ball screws. This double spindle system turns it into a purely mechanical one Setting a torque achieved, the setting without great effort with a correspondingly high speed he follows.

The invention is therefore based on the object of an actuator for a valve of a turbine, in which with a particularly low fire risk a trouble-free Operation of the valve is guaranteed. Another The object of the invention is to have a steam turbine low risk of fire disruption to operations specify.

The on an actuator for a valve of a turbine task is performed by an electromechanical Actuator with a push rod for setting one Opening position of the valve, with an electric motor for Drive of the push rod released, the push rod and the Electric motor with each other via a transmission device are connected by which transmission device depending on axial displacement of the push rod a changing torque can be generated.

An electromechanical actuator with a transmission device, through which depending on the stroke of the push rod changing torque can be generated is particularly advantageous with such valves, which are on the push rod Force to be exerted when closing or opening the valve changed depending on the stroke of the push rod. This With valves e.g. occur in a steam turbine at where the steam pressure is on the valve cone and this supports the closing process or the valve cone keeps closed. With such a valve there is initially one great force (vapor pressure x effective valve cone area) overcome to open the valves slightly. Once a certain Opening cross-section, there is a pressure relief, so that each time the opening process is smaller Force to move the push rod is necessary. Depending on the size, load and requirements on the valve, in particular the opening and closing process (closing speed etc.), the transmission device can accordingly be designed. By using an electric motor is also a fire risk compared to actuators with oil hydraulics significantly reduced.

The electric motor is preferably a speed controlled one Synchronous motor trained. Such a synchronous motor allows especially in connection with a servo amplifier, a highly precise position control with control accuracy of about 0.1 mm with an engine power up to about 30 kW. The servo amplifier acts as a frequency converter and enables a general or position-dependent reduction of the Motor current and motor speed. With a suitable adjustment the operating parameters can all be practically required Drive power and drive positioning speeds be provided.

To implement the rotary motion of the electric motor in a The linear movement provided for driving the push rod is Transmission device preferably as a crank drive, a planetary gear or the like executed.

A crank drive is a feed-dependent torque power transmission possible. In addition, with a quick Closing the valve, as is the case with a Quick closing of a valve occurs in a turbine, one necessary end position damping already through the crank drive be achieved. Additional speed reduction devices during the last of the valve plug (Sealing piece) into the valve seat can therefore depending on the requirement be disregarded. A crank drive has here via a crank element, in particular a crank disk, which rotates around an axis of rotation and on which the push rod attacks at a connection point, the connection point from the axis of rotation of the crank element (crank disc) is spaced. When the crank disc rotates the associated push rod runs between two maximum end positions along the main axis of the push rod a linear motion. In these end positions is over the crank disc can generate a very high torque, because at a rotation of the crank disk in the direction of the thrust axis in only a very small linear distance traveled in the respective end position becomes.

The actuator is preferably designed so that at one Reaching a closed position of the valve between the Main axis of the push rod and a connecting line between the connection point at which the connecting rod to the Crank disk attacks, and the axis of rotation at an angle in Range between 5 ° and 20 °, preferably about 10 °, formed. The connection point is thus in the closed position of the Valve near a maximum end position, so that at a rotation of the crank disc high torque and therefore a high force can be transmitted to the push rod. Consequently is particularly easy to open due to the actuator of the valve allows without a particularly powerful and / or to provide a torque-controlled electric motor. The push rod is preferably with a connecting rod connected at the junction, especially one crank pin firmly connected to the crank disk. The connecting rod is in one plane, in the main axis the push rod lies, rotatable with the push rod and connected to the crank pin.

Through the transmission device, especially the crank drive, is a feed-dependent torque-force conversion also for applications in which to open a Valve has a high feed force of, for example, approximately 200 kN is required, can be easily implemented. Through a change the crank radius (the distance of the connection point from the axis of rotation) or by shifting the point of use, i.e. the position that the junction in assumes the closed position of the valve, the characteristic curve (Torque characteristic) of the crank drive to different Requirements are adjusted. For example, for a Quick-closing valve of a steam turbine the choice of geometry the crank disc with a view to providing a very high force to open the valve and in the event of a quick close effective restoring force of a spring energy pack so that the highest possible acceleration force the crank drive is exercised.

An actuator with such a transmission device also offers the advantage that end position damping already can be taken over by the rotating crank disc. This is particularly important in a quick close case, because on the one hand the valve with a medium speed from e.g. 2 m / s must close, on the other hand the valve cone only at a speed of e.g. 0.07 m / s on the valve seat may touch down. Without such cushioning would namely the valve cone almost unbraked in the Drive the valve seat and could itself be damaged or damage the valve seat.

Through a spring storage package (return spring system), which in the event of a quick close, an even closing speed the push rod is in the area of the end position a larger crank angle is available so that the crank disc is accelerated further in this area. The larger crank angle and the acceleration on the crank disc therefore excellent in the end position range for end position damping be used.

The actuator preferably has an electromagnetic one Tooth clutch on which transmits power from the electric motor on the push rod, in particular on the transmission device, guaranteed. Preferably the electromagnetic Coupling a positive coupling, in the two Coupling parts interlock positively and thereby without a significant contact pressure of these two coupling parts force and torque transmission takes place. With a non-positive clutch, however, the two Coupling parts pressed together at high pressure, so that in this way a force and torque transmission to a significant extent takes place.

The electromagnetic clutch ensures that Rapid closing, the masses to be accelerated are extremely low are reached and thereby achieve a minimum closing time becomes. When the clutch is opened, there is a separation the crank drive from the electric motor and one Rotation system associated with the electric motor, e.g. comprehensive one Gearbox and a drive shaft for the crank drive.

The electromagnetic clutch preferably has at least three independent coil systems (excitation coils) open, even if a coil system fails as well as keeping the tooth coupling closed is. This system of independently operated Coil systems in which the failure of a coil system Clutch is still functional, is called n - 1 of n - Security technology. Preferably the clutch three independent coil systems and is therefore in a 2-of-3 security technology. To the clutch To keep closed, the force of two coils is sufficient out. The clutch can still be opened even if if a coil continues to pull the clutch together and the two remaining coils for releasing the clutch are switched. The coupling preferably has a spacing element, in particular a spring, which in the open Condition of the clutch an engagement of the clutch parts prevented each other. Against this spacing element the coil systems must close the clutch Act. The coupling is preferably designed here that all three coil systems (all n coil systems) work need to close the clutch.

The tooth coupling preferably has a coupling axis rotatable clutch disc on which clutch disc along the coupling axis in engagement with one with the Electric motor connected drive shaft can be brought. The The coupling axis preferably coincides with the axis of rotation the transmission device, the crank drive. The clutch also has a clutch hub, in one embodiment, the coupling hub directly is positively connected to the clutch disc and one Spacing of the coupling hub via the spacing means, in particular a spring connected by the transmission device is. In another embodiment, the clutch disc with the coupling hub using a spacer, in particular a spring, connected and along the coupling axis can be brought into engagement with the coupling hub. In both Cases must only when opening and closing the clutch a small mass can be moved to separate the electric motor to reach from the transmission device.

The actuator preferably has a return spring system on which is connected to the push rod and a force on the push rod in the direction of the closed position of the valve exercises. Especially in the event of a short circuit closing the valve via the return spring system exerting a corresponding force on the push rod reached.

The tooth coupling is preferably so through a coupling bearing stored that at most when disengaging the tooth clutch a small force is to be applied. More preferably includes the clutch bearing a ball joint. The clutch disc is in a particularly preferred embodiment of at least one, held in the ball joint support rod. This configuration of the tooth coupling is such can be disengaged with only a small force. In particular comes it does not get caught by high static friction Tooth clutch, which prevents disengagement of the tooth clutch could be.

The task aimed at a steam turbine is performed by a such a steam turbine solved for setting a steam flow has a control valve, the control valve via opened and closed an actuator described in more detail above can be.

The advantages achieved with the invention are in particular in that provided by the drive for the push rod Electric motor a pressure oil-free operation of the actuator is possible. So that is in use The risk of fire is particularly low in a steam turbine. moreover the actuator can be installed in any position, and can in particular be used as a replacement without much effort for an actuator with decentralized hydraulic supply be used. The electric motor is by means of a suitable one Activation in a particularly simple manner to different types Customizable requirements so that the actuator is special is flexible. The transmission device, in particular the crank drive is also easy to the adaptable to different requirements. The components of the actuator, especially the electric motor and the electromagnetic tooth clutch, are simple executable and therefore particularly easy to maintain.

FIG 1 und 2

einen Längsschnitt durch einen jeweils schematisch dargestellten Stellantrieb mit einem Ventil,

FIG 3

einen Ausschnitt eines Schnittes durch eine Hochdruck-Dampfturbine mit zwei Regelventilen und

FIG 4

einen Längsschnitt durch eine Zahnkupplung,

FIG 5

eine Aufsicht auf die Zahnkupplung 40 der Figur 4.

The invention is described with reference to an exemplary embodiment explained in more detail in the drawing. The drawing is partially schematic and not to scale and, for the sake of clarity and understanding, only includes the components of an actuator and a steam turbine that are important for the explanation. Show it:

1 and 2

3 shows a longitudinal section through an actuator with a valve, each shown schematically,

FIG 3

a section of a section through a high pressure steam turbine with two control valves and

FIG 4

a longitudinal section through a tooth coupling,

FIG 5

a top view of the tooth coupling 40 of Figure 4.

In Figure 1, a steam valve 2 is in a closed position a steam inflow 4, a steam outflow 5 and a valve seat 7 arranged therebetween. In the valve seat 7 is a sealing piece 6, a valve cone 6, which the valve 2 closes. The valve cone 6 has Valve connector 3 to which an actuator 1 is connected is. The actuator 1 has one along one Main axis 13 extending push rod 10, which with a return spring system 12 is connected. The push rod 10 is on the one hand with the valve connector 3 and on the other positively connected to a cross head 15. The Cross head 15 is in engagement with a linear guide 14, so that the push rod 10 is only a linear movement along their main axis 13 can perform. On the cross head 15, a connecting rod 11 is arranged so that it is in a Plane in which the main axis 13 of the push rod 10 lies, is rotatable. The connecting rod 11 is also in this Plane rotatable with a crank pin 34 of a transmission device 30 connected. The transmission device 30 has a crank drive 31, a crankshaft. The crankshaft 31 has a crank disk 33 which is about an axis of rotation 32 is rotatable in the plane of the push rod 10. The crank pin 34 is spaced apart from the axis of rotation 32 and positively connected to the crank disc 33. It therefore provides a connection point 34 between the crank disk 33 and the push rod 10. The crank disc 33 is one with an extending along the axis of rotation 32 Coupling hub 45 firmly and positively connected. In Direction of the axis of rotation 32 connects to the transmission device 30 a tooth coupling 40. The tooth coupling 40 has a around the coupling axis 42 (the axis of rotation 32) rotatable clutch disc 43. The clutch disc 43 is via a spacer 44, in particular a plate spring, connected to the coupling hub 45. On which the Clutch disc 43 facing end has the clutch hub 45 a reaction gear 36 in the circumferential direction. This reaction gear 36 is designed as a hollow shaft Surround drive shaft 21. The drive shaft 21 faces the reaction gear 36 opposite an action gear 47. In the direction of the axis of rotation 32, the reaction gear 36 and the action gear 47 opposite the clutch disc 43 a clutch disc toothing 46. This clutch disc toothing 46 is for both Engagement in the action gear 47 as well as the reaction gear 36 trained. The drive shaft 21 has three coil systems 41 (excitation coils), each consisting of two by one There is an angle of 180 ° spaced excitation coils. In the direction of the axis of rotation 32 the coil systems 41 opposite the clutch disc 43 has a magnetic Conclusion 48, by which when creating a electrical current to the coil systems 41 an axial displacement the clutch disc 43 against the restoring force of the spacing means 44 with an engagement of the clutch disc toothing 46 in the action gear 47 and the reaction gear 36 takes place. On the drive shaft 21 is a Multi-speed transmission 22 connected, which with an electric motor 20 communicates. The storage of the rotatable Parts, in particular the drive shaft 21 and the clutch hub 45, was preferably carried out by means of plain bearings.

A measuring transducer 25 engages on the push rod 10, which the position and speed of the push rod 10 or valve spindle is used. Measured values of the transmitter 25 can be fed to an opening regulator 24. The opening regulator 24 controller signals 26 can still be supplied. The opening regulator 24 is connected to a servo amplifier 23. The servo amplifier 23 is used to control the motor 20 and the Coil systems 41. The servo amplifier 23 is preferred executed as a frequency converter. It is backed up by a battery Power supply 29 with electrical current provided. It has 28 signals for triggering via an input a quick close as well as a load shedding. Via an output 27 can from the servo amplifier 23 different controller interference signals can be picked up.

In Figure 2, an actuator 1 is similar to that Actuator 1 shown in Figure 1. Differentiate these only in the illustrated embodiment the design of the coupling 40 and the connection of the Clutch 40 to crank drive 31. For description of the valve, the push rod, the electric motor as well as other elements of the actuator refer to the explanations referred to Figure 1. According to Figure 2 is the clutch hub 45 positively with the clutch disc 43 connected. The coupling hub 45 is via a spacer 44, in particular a plate spring, with the crank disk 33 connected. The plate spring 44 is designed that it keeps clutch 40 open, i.e. the clutch disc 43 axially spaced from the drive shaft 21, so that clutch 40 remains open. At the clutch hub 45 is an axial serration 35 is provided with the crank drive 31. This results in the implementation of a rotary movement of the Clutch disc 43 in a rotational movement of the crank disc 33. In the drive shaft 21 is in turn axially from the clutch disc 43 spaced an action gear 47 is provided. This action gear 47 has axially opposite Clutch disc 43 on a reaction gear 36, which for a positive engagement in the action gear 47 is formed is.

When the valve is activated, the rotational movement the shaft of the electric motor, not shown 20 via a torque conversion of the multi-speed transmission 23 transferred to the hollow drive shaft 21. The latter is via the electromagnetic clutch 40 with the crank disk 33 connected. Sits on the crank disk 33 from the axis of rotation 32 offset (crank radius) of the crank pin 34. By a rotation of the crank disc 33 is positive crosshead 15 connected to the push rod 10 via the Connecting rod 11 generates a linear movement of the push rod 10. The push rod 10 is already in the Closed position of the valve 2 by the restoring force of the Return spring system 12, which as a valve disk spring storage package executed, charged. With an opening movement of the actuator 1 becomes the return spring system 12 stretched further and reached in the open position of the valve 2 its maximum restoring force.

For a quick closing of the valve 2, the coil systems 41 de-energized (closed-circuit principle). The introduction a quick close occurs, for example, with a Rapid turbine shutdown, in the event of a load shutdown due to personal use, in the event of a load cut-off to the rated speed of the assigned Turbine as well as in the event of a power failure. Switching off the coil systems 41 eliminates this magnetic attraction between the coil system 41 and the clutch disc 43, whereby the electromagnetic clutch 40 the spacer due to the restoring force 44 opens. As a result, the drive shaft 21 with the attached Multi-speed transmission 22 and the electric motor 20 of that Crank drive 31 separately. So the torque of the electric motor 20 no longer against the restoring force of the return spring system 12 effective. The valve 2 thus goes with one fast response time of, for example, 100 ms in its Closed position.

In the embodiment described in Figure 1 only the small mass of the clutch disc moved axially. According to the embodiment of Figure 2 with a simple clutch toothing, in which the action gear 47 is arranged directly opposite the reaction gear 36, the clutch hub 45 is also closed in the axial direction move. In both cases the distance is between the toothing of the clutch disc 46 or 36 from the toothing the drive shaft (action gear 47) so dimensioned that an unhindered turning against each other is possible. The same applies to the radial spacing between the coupling hub 45 and the drive shaft 21 surrounding it The clutch 40 is closed by an application of the coil systems 41 with an electric current, whereby a magnetic attraction from the coil systems 41 to the magnetic yoke 48 of the clutch disc 43 is exerted, and thus the clutch 40 in the drive shaft 21 engages. When the clutch disc 43 engages in the drive shaft 21 are the corresponding gears 36, 46 and 47 according to the selected embodiment connected with each other. This is a positive Torque transmission between the corresponding gears 36, 46 and 47. The tooth flanks are preferably case hardened and ground. With a positive intervention of the respective gears into one another, especially when a maximum opening of the valve 2, there is a surface pressure on the tooth flanks, creating static friction arises, which counteracts an opening of the clutch 40, especially when the clutch 40 is lubricated by Oil is done. If there is a lubricated static friction with one Coefficient of friction of about µ = 0.1 between the tooth flanks, are the tooth flanks are chamfered at an angle of approximately 11.5 °, to be able to easily overcome the frictional resistance.

Three two-part coil systems 41 are preferably provided, each coil system 41 two 180 ° on the drive shaft 21 has staggered excitation coils. The coil systems 41 are based on a two-out-of-three security technology designed, ensuring that the electromagnetic force from two coils is sufficient to the clutch against the restoring force of the spacer 44 (disc spring) to keep closed. For a closing the clutch, all three coil systems 41 must be functional his. The functionality is sufficient for opening the clutch 40 of two coil systems 41, so that a coil system 41 may still be live can and the clutch 40 is still opened. At a Failure of the power interruption of an excitation coil 41, so that this carries current even in the event of a short-circuit, opens the Clutch 40 anyway. This makes the availability as well the opening security of the clutch 40 increases.

In Figure 3 is a horizontal section through a high pressure steam turbine 8 shown. The steam turbine 8 has two control valves 2 arranged opposite one another. On each control valve 2 is an actuator 1, as in Figures 1 or 2 described, connected. The control valve 2 has a valve connector 3 for the actuator 1, a steam inflow 4, a steam outflow 5, a valve cone 6 and an associated valve seat 7. The steam turbine 8 has a turbine shaft 9 and a surrounding one Housing 18 on. On the housing 18 and on the turbine shaft 9, the turbine blades 16 are arranged. During the Operation of the steam turbine 8 passes steam 17 through the Control valves 2 into the steam turbine 8 and overdrive the blading 16 on the turbine shaft 9. The control valves 2 can be used as control valves and / or combined control and Quick-closing valves must be executed.

FIG. 4 shows a further embodiment in a longitudinal section the gear coupling 40. The coupling hub (45) is of one disc-like approach 111 completed. This disc-like Approach 111 is with a support rod 109 with the Clutch disc 43 connected. The support bar 109 is in one first ball joint 105B with the disc-like approach 111 connected. The support bar 109 is at its other end with a second ball joint 105A with the clutch disc 43 connected. With this configuration, the axial Serration 35 of Figure 2 can be dispensed with. The torque transmission to the transmission device 30 via the support rods 109. Through the bearing in ball joints advocates axial movement along the coupling axis 42 almost no static friction. The tooth coupling 40 is thus can be disengaged with only a small force. This prevents blocking the disengagement of the tooth clutch 40 by high frictional forces. This increases operational security increased.

FIG. 5 shows a top view of the tooth coupling 40 of the figure 4. You can see a saw blade-like formation of the disc-like Approach 111. This ensures that the handrails 109 remain freely movable during a rotation.

Claims (15)

1. Electromechanical actuating drive (1) for a valve (2) of a turbine, with a push rod (10) for setting an opening position of the valve (2), and with an electric motor (20) for driving the push rod (10), the push rod (10) and the electric motor (20) being connected via a transmission device (30), by means of which a changing torque can be generated, depending on the axial displacement of the push rod (10).
2. Actuating drive (1) according to Claim 1, wherein the transmission device (30) has a planetary gear.
3. Actuating drive (1) according to Claim 1, wherein the transmission device (30) has a crank mechanism (31).
4. Actuating drive (1) according to Claim 3, wherein the crank mechanism (31) has a crank disc (33) rotatable about an axis of rotation (32), the push rod (10) engaging on the crank disc (33), for example via a connecting rod (11), at a connection point (34) at a distance from the axis of rotation (32).
5. Actuating drive (1) according to Claim 4, wherein, when a closing position of the valve (2) is reached, starting from the axis of rotation (32), an angle in the range of between 5° and 20°, preferably about 10°, is formed between the connection point (34) and the main axis (13).
6. Actuating drive (1) according to one of the preceding claims, wherein an electromagnetic denture clutch (40) is provided between the transmission device (30) and the electric motor (20).
7. Actuating drive (1) according to Claim 6, wherein the electromagnetic denture clutch (40) has at least three coil systems (41) independent of one another, and, even if one coil system (41) fails, it is ensured that the denture clutch (40) is opened and also is kept closed.
8. Actuating drive (1) according to Claim 6 or 7, wherein the denture clutch (40) has a clutch disc (43) which is rotatable about a clutch axis (42) and which can be brought along the clutch axis (42) into engagement with a drive shaft (21) connected to the electric motor (20).
9. Actuating drive (1) according to Claim 8, wherein the clutch disc (43) is connected to a clutch hub (45) by a spacer means (44), in particular a spring, and can be brought along the clutch axis (42) into engagement with the clutch hub (45).
10. Actuating drive (1) according to Claim 8, wherein the clutch disc (43) is connected positively to a clutch hub (45) which is connected to the transmission device (30) by a spacer means (44), in particular a spring.
11. Actuating drive (1) according to one of the preceding claims, wherein a return spring system (12) is arranged on the push rod (10).
12. Actuating drive (1) according to one of Claims 6 to 11, wherein the denture clutch (40) is mounted by means of a clutch bearing (102) in such a way that at most a slight force has to be applied in order to disengage the denture clutch (40).
13. Actuating drive according to Claim 12, wherein the clutch bearing (102) comprises a ball joint (105).
14. Actuating drive (1) according to Claim 8 and 14, wherein the clutch disc (43) is held by at least one holding rod (109) mounted in the ball joint (105).
15. Steam turbine with an actuating valve (2) for setting a steam stream, for which valve an actuating drive (1) according to one of the preceding claims is provided.

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